DE10203716C1 - Tapering plant-pot made of fibrous, biologically decomposable materials, in particular, coconut fibres comprises an entry ring section with a transverse shoulder and a negative taper angle - Google Patents

Abstract

The tapering plant-pot made of fibrous, biologically decomposable materials, in particular, coconut fibres comprises an entry ring section (2) with a transverse shoulder (3) and a negative taper angle between 0.5 and 10 . The purpose of these features is to facilitate machine handling of vertical stacks of such plant-pots.

Description

The invention relates to a plant or culture vessel made of fibrous, biodegradable ren materials, in particular from coconut fibers, which have an open-topped vessel form an input ring portion to which a cross ver with its cross section running ring section connects to which in turn a conical in cross section Pot body follows.

Such a planter is known approximately from DE 195 16 572 C2, wherein by cutting a round blank and overlapping ribs in a pressing tool are formed on the circumference, which the vessel wall during transport and the Handha exercise should strengthen. However, the vessels produced in this way are being separated a stack of pots formed from a plurality of stacked vessels un cheap because they slide into each other and stick together. This makes a ver practically impossible individually.

Reinforcing ribs have also been used for a self-supporting pot made from coconut fibers, which are pressed on the inside and outside (AU-B-46983/85).

Another known design (DE 199 33 150 A1) aims at space and For transport reasons, stack the planters into one another and after transport  at the place of use before filling again. In doing so, detention friction effects and positive locking of the conical pot body by the known Ribs and through so-called indentations (cavities from outside or inside in the pot wall) can be avoided. While such ribs the production volume increase in coconut fibers and impair the root growth of the plants and The required stabilization can lead to the insertion of very complicated press tools fundamentally thanks to the density of the pot wall, even with pot walls small wall thickness and conical pot body walls can be achieved.

For the rest, only pots made of plastic or clay are known (brochure TEKU plant pots 1993 ), in which the opening angle range of the entrance ring section is positive, ie is designed to widen upwards. The pots slide into one another when stacked, stick together and are very difficult to separate.

The invention has for its object, the nesting and one again to separate the vessels in potting machines even without ribs, on pull or knobs u. Like. And thus to achieve a favorable stackability and to achieve the least possible static friction effect and without any form close to get along.

The task is fiction, in the subject initially mentioned solved according to that for the treatment of a vertical stack of pots, which in a potting machine can be separated, the entrance ring section with its height the pot body wall in a negative angular range of 0.5-10 ° narrowing at the top, is conical. This creates a significant interlocking sliding of the pots of a built-up stack of pots avoided and the pots can can be easily separated from the stack of pots. This also ribs, indentations, Pimples u. The like. superfluous. Surprisingly, such an undercut  can be easily produced by the previous pressing. The manufacturing process need not be changed. However, it is also possible to back this up cutting the input ring section z. B. by a method according to the German to produce patent 198 198 047 C1.

The undercut of the input ring section can also be carried out in this way be that with nested smooth-walled pot bodies between each adjacent, parallel running pot body walls a tunable gap is maintained. Such a tunable gap has shown in experiments that the individual planters by themselves in the pot machine after separation drop out at the bottom, so that the static friction forces and the form fit are as large as possible are canceled.

The geometric shape of the cross-section of the vessel can be broken down according to further characteristics by influencing the fact that one with a negative Angle to the horizontal provided ring section with the wall thickness of the rest Connects walls of the vessel. A slipping of the individual pot bodies per is not possible. The pot bodies lie with the horizontal ring cut on top of each other, so that very tall columns of nested pot bodies that represent a high load for deeper-lying pot bodies without further can be caught.

An alternative embodiment, the stacking and singling still further supported, is achieved in that in addition to the undercut Angular range of the approximately horizontal ring section to one at the vessel entrance shaped flange ring runs at a negative angle of approx. 2-8 °.  

In a further embodiment it is proposed that the cone angle of the pot body pers is different from the cone angle of the input ring section. In general, the cone angle of the entrance ring section will be steeper than that Cone angle of the pot body.

A variant results from the fact that the largest at the entrance ring section Diameter of the vessel forming flange ring is connected. This Flange ring does not take part in the stacking function, but is for the sake of manufacturing technique desirable because a circular boundary already in Press tool can be made, so no additional work step is necessary and yet a largely circular edge is created.

The desired gap in order to avoid a static friction effect can be found on ver affect different species. A first type provides that the cone angle of the Input ring section depends on the diameter of the flange ring.

It is advantageous that a larger flange ring has a larger cone angle of the entrance ring section.

Another type of gap determination is provided so that at least the wall thickness of the pot body depending on the diameter of the entrance ring section can be determined.

The gap can be determined according to other characteristics such that the approximately horizon located between the entrance ring section and the pot body tale ring section in its width depending on the wall thickness of the pot body is selectable.  

Another gap determination can be made by changing the height of the entrance ring section depending on the gap to be selected between one another inserted vessels is selectable.

The principle of the invention can be applied in a variety of pot sizes the. It is advantageous to measure rows of pots from 10 mm to 400 mm in diameter sen are provided on the input ring portion.

In a further development of the invention it is provided that the input section, which approximately horizontal ring section and possibly also the flange ring due to a denser Fiber structure that is mixed with latex is made. The fiber-reinforced flange ring has the additional advantage that the pot machine gripper has a stable hold find zone and in addition it is possible to separate the stack upwards is. The higher compression of the upper edge area and the higher fiber and The latex content prevents fraying of the upper edge (the pot remains dimensionally stable even during the culture phase) and when inserting the planter at the final location in the ground, avoids the solid compression an increased evaporation of water over the otherwise brittle and frayed pot rim.

It is also suggested to reinforce the upper part of the planter that the inlet ring section and, if necessary, the flange ring are immersed in an Latex or wax sealable. Compressed coconut fibers in verbin latex have the natural behavior of slow decompression. The sealing further slows down this process.

In the drawing, embodiments of the invention are shown, the next be explained in more detail.  

Show it:

Fig. 1 shows an axial cross section through two nested vessels in a first embodiment and

Fig. 2 shows an axial cross section through two nested vessels in a second embodiment.

A plant or culture vessel 1 consists of fibrous, biodegradable materials, in particular coconut fibers. From the coconut fibers a one-piece, open-topped vessel 1 with an input ring section 2 is formed, which is essentially done by pressing a thin round blank in a press tool. At the input ring section 2 with a height 2 a, a horizontal Ringab section 3 connects, the cross section of which can be approximately sharp-edged and has a width 3 a. The ring section 3 then continues in a conical pot body by 4 to a bottom, the pot body 4 , z. B. can be performed in the manner according to DE 199 07 577 C1.

For the purpose of treating a vertical pot stack 5 , which is separated in a pot machine, the entrance ring section 2 with its height 2 a is conical in an angular range 9 of 0.5-10 °, narrowing upwards. This creates between nested, smooth-walled pot bodies 4 , each between two adjacent, parallel, parallel pot body walls 4 a from a tunable, ie adjustable according to special criteria gap 6 , which is maintained when Ineinan derstecken, so that no difficulties in separating occur.

Another criterion for setting the gap 6 is designed such that the horizontal ring section 3 with the wall thickness 7 of the other walls 4 a of the vessel 1 adjoins the input ring section 2 . The width of a 3 also serves as Regularium.

Furthermore, the cone angle 8 of the pot body 4 is designed differently from the negative angular range 9 of the input ring section 2 ( FIGS. 1 and 2).

Another embodiment is shown in FIG. 2. There, in addition to the negative angular range 9, the horizontal ring section 3 is formed at an angular range 13 of approximately 82-88 °, so that the ring section 3 extends to a flange 11 at the entrance to the vessel at an angle 14 of approximately 2-8 °.

Referring to FIGS. 1 and 2 of the largest diameter 10 of the vessel 1 forming flange 11 is also connected to the input ring section 2, which can be ten in a pressing tool in one operation with ausgeschnit as already described, so that a special working step is saved. The flange ring 11 also increases the stability of the planter 1 .

As a further rule for setting the gap 6, it is provided that the cone angle 9 of the input ring section 2 is dependent on the diameter 10 of the flange ring 11 . A larger flange ring 11 corresponds to a larger cone angle 9 of the input ring section 2 .

The wall thickness 12 of the pot body 4 can also be determined in all cases as a function of the diameter 10 of the input ring section 2 . Equally, it is provided that the width of the horizontal ring section 3 located between the entrance ring section 2 and the pot body 4 3 a can be selected as a function of the gap 6 to be selected between two vessels 1 located one inside the other.

Another Regularium for avoiding a static friction effect or form fit provides even before that the level 2 a dependency of the input ring portion 2 in the Ab is selected to be selected gap 6 between nested vessels. 1

The above-mentioned regulations can be applied to top rows of 10 mm to 400 mm diameter 10 at the entrance ring section 2 .

LIST OF REFERENCE NUMBERS

1

Planter or culture vessel

2

Input ring section

2

a Height of the entrance ring section

3

horizontal ring section

3

a width

4

conical pot body

4

a pot body wall

5

pot stack

6

gap

7

wall thickness

8th

Cone angle of the pot body

9

Cone angle of the entrance ring section

10

largest diameter of the vessel

11

flange

11

a flange ring diameter

12

Wall thickness of the pot body

13

angle range

14

angle

Claims (14)

1. planting or culture vessel made of fibrous, biodegradable materials, in particular of coconut fibers, which form an open-topped vessel with an entry ring section, to which a ring section with a transverse cross section adjoins, which in turn is followed by a conical pot body in cross section, characterized in that for the treatment of a vertical pot stack (5) that is machine in a Topfma individualizable, the input ring section (2) to its height (2a) to the Topfkörperwandung (4 a) in a negative angle range of 0.5-10 °, narrowing towards the top, is conical. 2. Planting or culture vessel according to claim 1, characterized in that when nested smooth-walled pot bodies ( 4 ) between each because neighboring, parallel pot body walls ( 4 a) from a tunable gap ( 6 ) is maintained. 3. planting or culture vessel according to one of claims 1 or 2, characterized in that at the input ring portion ( 2 ) with a negative angle ( 14 ) to the horizontal ring portion ( 3 ) with the wall thickness ( 7 ) of the remaining walls ( 4 a) of the vessel ( 1 ) connects. 4. planting or culture vessel according to one of claims 1 to 3, characterized in that in addition to the undercutting angular region ( 9 ) of the approximately horizontal ring portion ( 3 a) to a flange ring ( 11 ) formed on the vessel entrance at a negative angle ( 14 ) runs from approx. 2-8 °. 5. Planting or culture vessel according to one of claims 1 to 4, characterized in that the cone angle ( 8 ) of the pot body ( 4 ) is different from the cone angle ( 9 ) of the input ring section ( 2 ). 6. Planting or culture vessel according to one of claims 1 to 5, characterized in that a flange ring ( 11 ) forming the largest diameter ( 10 ) of the vessel ( 1 ) is connected to the input ring section ( 2 ). 7. planting or culture vessel according to claim 6, characterized in that the cone angle ( 9 ) of the input ring portion ( 2 ) on the diameter ( 11 a) of the flange ring ( 11 ) is dependent. 8. Planting or culture vessel according to claim 7, characterized in that a larger flange ring ( 11 ) corresponds to a larger cone angle ( 9 ) of the input ring section ( 2 ). 9. planting or culture vessel according to one of claims 1 to 8, characterized in that at least the wall thickness ( 12 ) of the pot body ( 4 ) depending on the diameter ( 10 ) of the input ring portion ( 2 ) can be determined. 10. planting or culture vessel according to one of claims 1 to 9, characterized in that between the input ring portion ( 2 ) and the pot body ( 4 ) be approximately horizontal ring portion ( 3 ) in width ( 3 a) depending on the speed Wall thickness ( 12 ) of the pot body ( 4 ) can be selected. 11. planting or culture vessel according to one of claims 1 to 10, characterized in that the height ( 2 a) of the input ring section ( 2 ) depending on the gap ( 6 ) to be selected between nested vessels ( 1 ) can be selected. 12. Planting or culture vessel according to one of claims 1 to 11, characterized in that rows of pots of 10 mm to 400 mm in diameter ( 10 ) measured at the entrance ring section ( 2 ) are provided. 13. Planting or culture vessel according to one of claims 1 to 12, characterized in that the input ring section ( 2 ), the approximately horizontal ring section ( 3 ) and possibly also the flange ring ( 11 ) due to a denser fiber structure which is mixed with latex , is manufactured. 14. Planting or culture vessel according to one of claims 1 to 13, characterized in that the input ring section ( 2 ) and possibly the flange ring ( 11 ) can be sealed by means of an immersion bath in latex or in a wax.